Improved Stability and Performance of Surface Acoustic Wave Nanosensors Using a Digital Temperature Compensation

Frontiers in sensors Pub Date : 2021-06-14 DOI:10.3389/fsens.2021.617484

S. Balashov, J. Rocha, M. R. F. Hurtado, J. A. L. Prestes, A. F. M. de Campos, S. Moshkalev

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引用次数: 2

Abstract

Surface Acoustic Waves (SAW) sensors are known to be an excellent choice for the measurement of a small concentration of analytes in gas mixtures. The use of this type of sensor has been limited until now in the industrial environment due to the sensitivity of its response to temperature variations. To overcome this problem, thermal stabilization of equipment is normally used. We propose here a simple procedure of compensation of thermal drift in SAW sensors, allowing the measurements to be performed in temperature intervals of up to 20 degrees without any thermal stabilization of the sensitive element of a sensor. By monitoring the temperature of the key points of the sensor and applying the proposed polynomial compensation, it is possible to reduce the influence of thermal instabilities of the ambient temperature to the response more than four times. The method is illustrated by a temperature compensated SAW humidity sensor with a graphene oxide nanofilm as water molecules’ sensitive element. The results show enhanced performance of the sensor over a large temperature interval.

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采用数字温度补偿提高声表面波纳米传感器的稳定性和性能

表面声波(SAW)传感器被认为是测量气体混合物中小浓度分析物的绝佳选择。由于其对温度变化的响应灵敏度高，这种类型的传感器的使用到目前为止在工业环境中一直受到限制。为了克服这个问题，通常使用设备的热稳定。我们在这里提出了一种简单的SAW传感器热漂移补偿程序，允许在高达20度的温度间隔内进行测量，而无需传感器敏感元件的任何热稳定。通过监测传感器关键点的温度并应用所提出的多项式补偿，可以将环境温度的热不稳定性对响应的影响降低四倍以上。以氧化石墨烯纳米膜作为水分子敏感元件的温度补偿SAW湿度传感器为例说明了该方法。结果表明，在较大的温度区间内，传感器的性能得到了提高。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in sensors

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